Displaying Visual Information of Views Captured at Geographic Locations

ABSTRACT

A method, apparatus and computer program for displaying at least a part (101a) of first visual information (101) that is a view (102a′), from a first geographical location (103); generating a visualisation (400) configured to visually link the display of at least a part (101a) of the first visual information (101) with a display of at least a part (201a) of second visual information (201) that is a view (202a′) from a second geographical location (203), wherein generating the visualisation comprises: determining a direction (112) of the second geographical location (203) with respect to the first geographical location (103); defining a virtual object (401) having: a virtual primary axis (402) aligned with the direction (112), a virtual distal end surface (403), at least a part of which defmes a first virtual display surface (403a), and at least one virtual inner surface (404), at least a part of which defmes at least a second virtual display surface (404a); displaying on the first virtual display surface (403a) at least a part (201a) of the second visual information (201); and displaying on the at least second virtual display surface (404a), at least a part (301a) of third visual information (301).

TECHNOLOGICAL FIELD

Examples of the present disclosure relate to displaying visualinformation of views captured at geographic locations. Some examples,though without prejudice to the foregoing, relate to a method, apparatusand computer program for rendering first and second visual informationof first and second views captured at first and second geographicallocations. Certain examples relate to rendering first and secondpresence capture information of first and second scenes captured atfirst and second presence capture locations.

BACKGROUND

In ‘presence capture’ systems, visual information representative of oneor more views/scenes in one or more directions may be captured by one ormore image capture devices located at a particular single geographicreal-world location. For example, a panoramic or a 360° (27 radians)view of a location may be captured, or even a 720° (47 steradians) view,i.e. 360° view about each of a vertical and horizontal axis. Thecaptured visual information may be displayed on a display device toenable a viewer to look around/pan around the visual information toperceive varying directions of views of the visual information capturedat the geographic location. In such a manner the viewer may experiencebeing virtually ‘present’ at the geographical location. Such capturedspatial visual information, e.g. images/videos of views/scenes/a visualenvironment captured at a particular geographical location in variousdirections, may be referred to as ‘presence capture information’.

Conventional systems for displaying presence capture information are notalways optimal. Such systems may not effectively be able tosimultaneously display first presence capture information (of a firstpresence capture location) and second presence capture information (of asecond presence capture location) in an intuitive manner that isminimally disorientating or distracting to the viewer who may be deeplyimmersed in viewing the presence capture information. This can cause areduction in the viewer's level of immersion and/or adversely impact theviewer's user experience of consuming presence capture content.

The listing or discussion of any prior-published document or anybackground in this specification should not necessarily be taken as anacknowledgement that the document or background is part of the state ofthe art or is common general knowledge. One or more aspects/examples ofthe present disclosure may or may not address one or more of thebackground issues.

BRIEF SUMMARY

According to various but not necessarily all examples of the disclosurethere is provided a method comprising:

displaying at least a part of first visual information that is a firstview, from a first geographical location;

generating a visualisation configured to visually link the display ofthe at least a part of the first visual information with a display of atleast a part of second visual information that is a second view from asecond geographical location,

wherein generating the visualisation comprises:

-   -   determining a direction of the second geographical location with        respect to the first geographical location;    -   defining a virtual object having:        -   a virtual primary axis aligned in dependence on the            direction,        -   a virtual distal end surface, at least a part of which            defines a first virtual display surface, and        -   at least one virtual inner surface, at least a part of which            defines        -   at least a second virtual display surface;    -   displaying on the first virtual display surface at least a part        of the second visual information; and    -   displaying on the at least second virtual display surface, at        least a part of third visual information.

According to various but not necessarily all examples of the disclosurethere is provided an apparatus comprising:

means configured to display at least a part of first visual informationthat is a first view, from a first geographical location;

means configured to generate a visualisation configured to visually linkthe display of the at least a part of the first visual information witha display of at least a part of second visual information that is asecond view from a second geographical location, wherein the meansconfigured to generate the visualisation comprises:

-   -   means configured to determine a direction of the second        geographical location with respect to the first geographical        location;    -   means configured to define a virtual object having:        -   a virtual primary axis aligned in dependence on the            direction,        -   a virtual distal end surface, at least a part of which            defines a first virtual display surface, and        -   at least one virtual inner surface, at least a part of which            defines        -   at least a second virtual display surface;    -   means configured to display on the first virtual display surface        at least a part of the second visual information; and    -   means configured to display on the at least second virtual        display surface, at least a part of third visual information.

According to various but not necessarily all examples of the disclosurethere is provided an apparatus comprising at least one processor; and

at least one memory including computer program code;

the at least one memory and the computer program code configured to,with the at least one processor, cause the apparatus at least toperform:

displaying at least a part of first visual information that is a firstview, from a first geographical location;

generating a visualisation configured to visually link the display ofthe at least a part of the first visual information with a display of atleast a part of second visual information that is a second view from asecond geographical location,

wherein generating the visualisation comprises:

-   -   determining a direction of the second geographical location with        respect to the first geographical location;    -   defining a virtual object having:        -   a virtual primary axis aligned in dependence on the            direction,        -   a virtual distal end surface, at least a part of which            defines a first virtual display surface, and        -   at least one virtual inner surface, at least a part of which            defines at least a second virtual display surface;    -   displaying on the first virtual display surface at least a part        of the second visual information; and    -   displaying on the at least second virtual display surface, at        least a part of third visual information.

According to various but not necessarily all examples of the disclosurethere is provided a computer program that, when performed by at leastone processor, causes the following to be performed:

displaying at least a part of first visual information that is a firstview, from a first geographical location;

generating a visualisation configured to visually link the display ofthe at least a part of the first visual information with a display of atleast a part of second visual information that is a second view from asecond geographical location,

wherein generating the visualisation comprises:

-   -   determining a direction of the second geographical location with        respect to the first geographical location;    -   defining a virtual object having:        -   a virtual primary axis aligned in dependence on the            direction,        -   a virtual distal end surface, at least a part of which            defines a first virtual display surface, and        -   at least one virtual inner surface, at least a part of which            defines        -   at least a second virtual display surface;    -   displaying on the first virtual display surface at least a part        of the second visual information; and    -   displaying on the at least second virtual display surface, at        least a part of third visual information.

According to various but not necessarily all examples of the disclosurethere is provided a non-transitory computer readable medium encoded withinstructions that, when performed by at least one processor, causes atleast the following to be performed:

displaying at least a part of first visual information that is a firstview, from a first geographical location;

generating a visualisation configured to visually link the display ofthe at least a part of the first visual information with a display of atleast a part of second visual information that is a second view from asecond geographical location, wherein generating the visualisationcomprises:

-   -   determining a direction of the second geographical location with        respect to the first geographical location;    -   defining a virtual object having:        -   a virtual primary axis aligned in dependence on the            direction,        -   a virtual distal end surface, at least a part of which            defines a first virtual display surface, and        -   at least one virtual inner surface, at least a part of which            defines at least a second virtual display surface;    -   displaying on the first virtual display surface at least a part        of the second visual information; and    -   displaying on the at least second virtual display surface, at        least a part of third visual information.

According to various but not necessarily all examples of the disclosurethere is provided a chipset comprising processing circuitry or a moduleconfigured to:

display at least a part of first visual information that is a firstview, from a first geographical location;

generate a visualisation configured to visually link the display of theat least a part of the first visual information with a display of atleast a part of second

visual information that is a second view from a second geographicallocation, wherein generating the visualisation comprises:

-   -   determining a direction of the second geographical location with        respect to the first geographical location;    -   defining a virtual object having:        -   a virtual primary axis aligned in dependence on the            direction,        -   a virtual distal end surface, at least a part of which            defines a first virtual display surface, and        -   at least one virtual inner surface, at least a part of which            defines        -   at least a second virtual display surface;    -   displaying on the first virtual display surface at least a part        of the second visual information; and    -   displaying on the at least second virtual display surface, at        least a part of third visual information.

According to various, but not necessarily all, embodiments of theinvention there is provided examples as claimed in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of various examples of the present disclosurethat are useful for understanding the detailed description and certainembodiments of the invention, reference will now be made by way ofexample only to the accompanying drawings in which:

FIG. 1A schematically illustrates first and second presence captureinformation captured at first and second presence capture locations;

FIG. 1B schematically illustrates a map of first and second presencecapture locations;

FIG. 2 schematically illustrates a virtual object:

FIGS. 3A and 3B schematically illustrate a visualisation visuallylinking a display of first and second presence capture information;

FIGS. 4A and 4B schematically illustrate a visualisation from a viewer'sperspective;

FIGS. 5A and 5B schematically illustrate further examples of avisualisation from a viewer's perspective;

FIG. 6 schematically illustrates a network of presence capture locationsand interconnecting visualisation links;

FIG. 7 schematically illustrates a network map of presence capturelocations and interconnecting visualisation links;

FIG. 8 schematically illustrates a method;

FIG. 9 schematically illustrates an apparatus; and

FIG. 10 schematically illustrates a further method.

DETAILED DESCRIPTION

Examples of a method, apparatus and computer program according to thepresent disclosure will now be described with reference to the Figures.

The Figures are not necessarily to scale. Certain features and views ofthe Figures may be shown schematically or exaggerated in scale in theinterest of clarity and conciseness. For example, the dimensions of someelements in the Figures may be exaggerated relative to other elements toaid explication.

Similar reference numerals are used in the Figures to designate similarfeatures. For clarity, all reference numerals are not necessarilydisplayed in all Figures.

The Figures schematically illustrate a method 800 comprisingcausing/enabling/facilitating:

-   -   displaying 801 at least a part 101 a of first visual information        101 that is a view 102 a′, from a first geographical location        “A” 103;    -   generating 802 a visualisation 400 configured to visually link        the display of the at least a part 101 a of the first visual        information 101 with a display of at least a part 201 a of        second visual information 201 that is a view 202 a′ from a        second geographical location “B” 203, wherein the generating of        the visualisation 400 comprises:        -   determining 802 a (e.g. calculating or receiving) a            direction 112 of the second geographical location 203 with            respect to the first geographical location 103 (such a            direction may correspond to a virtual line of sight of B            from A);        -   defining 802 b a virtual object 401 having:            -   a virtual primary axis 402 aligned in dependence on the                direction 112,            -   a virtual distal end surface 403, at least a part of                which defines a first virtual display surface 403 a, and            -   at least one virtual inner surface 404, at least a part                of which defines at least a second virtual display                surface 404 a;        -   displaying 802 c (e.g. simultaneously with and/or overlaying            the display of the first visual information 101) on the            first virtual display surface 403 a at least a part 201 a of            the second visual information 201; and        -   displaying 802 d on the at least second virtual display            surface 404 a, at least a part 301 a of third visual            information 301.

As schematically illustrated in FIG. 1A, the visualisation information101 may comprise: one or more images (or videos) 101 a-101 c of one ormore viewpoints 102 a′-102 c′ captured by an image capture device fromone or more directions 102 a-102 c at a geographical location 103, suchas a physical real-world location A. One or more parts 101 a-101 c ofthe visualisation information 101 (such as constituent images/videoscaptured in particular directions 102 a-c from the geographical location103) may be associated, e.g. not least via metadata, with thegeographical location 103 and the direction 102 a-c at which they werecaptured at so as to provide spatial visual information.

In some examples, the visualisation information 101 may comprise acomposite mosaic of captured images/videos so as to provide a panoramicview or viewpoint coverage of: 90, 120, 180 or 360 degrees (27 radians)about a vertical axis or complete viewpoint coverage of 720 degrees,namely two 360 degree views about each of a horizontal and verticalaxis, i.e. 47 steradians.

The visualisation information 101 may be captured by one or more imagecapture devices located at the particular geographic location 103capturing images/videos at varying directions 102 a-102 c from thegeographic location 103. For example, the visualisation information 101may be captured by a stationary image capture device, e.g. with aplurality of camera modules capturing images at differingviewpoints/directions 102 a-102 c, or an image capture device whoseorientation (e.g. pan/tilt) is adjusted to capture images at differingviewpoints/directions 102 a-102 c.

The visual information 101, may be presence capture information,captured by a presence capture device at a presence capture location.Such presence capture information, in addition to including visualinformation 101 associated with a location and direction of view (i.e.“spatial” visual information of the visual scene at the location), mayalso include audio information, i.e. directional spatial audio capturedat the particular geographical location 103 at various differingdirections/perspectives 102 a-c. In such a manner the presence captureinformation may comprise audio/visual content, such as views and sounds,captured at the presence capture location from variousdirections/perspectives 102 a-c so as to capture a real worldvisual/aural scene of a real world location so as to enable a recreationof a virtual visual/aural scene representative of the visual and auralenvironment of the real world location.

The second visualisation information 201 may be similar in nature to thefirst visualisation information 101, albeit captured from a secondgeographic location 203. For example, the second visualisationinformation 201 may correspond to second presence capture informationcaptured by a second presence capture device at a second presencecapture location.

The visualisation information may be pre-captured and pre-stored to beaccessed for display or it may be captured live and be transmitted forreception and display substantially in real time. The visualisationinformation may be displayed by a display device, not least for examplea virtual reality display system, such as a virtual reality near eyedisplay/headset, that may provide interactive viewing functionality suchthat the viewer turning his/her head controls the viewpoint direction ofthe visual information that is displayed so as to enable display of thevisual information at different perspectives/viewing at differentdirections. For example, this may enable a viewer to navigate around/panaround the displayed image/video of the visual information to view theimage/video from varying viewpoints/perspectives.

The visual information/presence capture information may bedisplayed/rendered on a presence capture information rendering device,such as, not least for example a head-mounted display (and binauralheadset) utilizing head tracking. The presence capture informationrendering system may enable a viewer to perceive the captured visual andaural environment of the presence captured geographic location, suchthat the viewer feels as though he/she is (virtually) present at thegeographic location. The presence capture may be done at a singleposition, which may then correspond to the position of a viewer whenviewing the presence capture information.

The display of at least a part of first visual information 101 maycomprise displaying a portion of the visual information 101 a which isless than its entirety. The displayed part of the visualisationinformation 101 may be dimensioned framed, cropped etc., such that onlya portion of the visualisation information 101 may be displayed at anyone time such that a viewer may pan his/her view within the visualinformation 101.

The display of at least a part of first visual information 101 maycomprise: selecting a particular live/real time presence capture stream(which is associated with a particular viewpoint direction 102 a and/ora particular image capture device orientated at the particular viewpointdirection 102a) for receiving and displaying visual information for theparticular viewpoint direction. Alternatively, the act of displaying atleast a part of first visual information 101 may comprise: selecting aparticular pre-captured presence capture file, or portion thereof,(which is associated with a particular viewpoint direction 102a) foraccessing and displaying visual information for the particular viewpointdirection 102a. Yet further, the act of displaying at least a part offirst visual information may comprise: receiving the first visualisationinformation, e.g. comprising visual information representative of viewsfrom 0-360°, determining a particular viewpoint direction 102 a andprocessing the visualisation information 101 to extract and render apart of the visualisation information 101 a so as to display a viewcorresponding to the determined viewpoint direction 102 a. In thisregard, the directional viewpoint 102 a may relate to a direction of aviewer's real world point of view.

The visualisation information may be received from a memory of a deviceseparate of the display device, such as a repository, a visualinformation provider, a server or a camera module over a wired orwireless network via one or more intermediate apparatuses and servers.The visual information need not necessarily correspond to a (single)view captured from a certain (single) camera, but it may be a compositeor fusion of at least two camera captures.

The display of the first visualisation information 101 may furthercomprise adjusting and rendering the visual information 101 so as todisplay a view 102 a′ from a particular viewpoint direction 102 a (e.g.a viewpoint direction 102 a that may dependent on a viewer's/user's realworld point of view). The same likewise may apply for the display of thesecond visual information 201.

The display of second visual information 201 may further comprisemodifying the second visual information 201 in dependence on adetermined real world point of view of a viewer/user, i.e. adjust oradapt the rendering of the visual information (such as skewing ordistorting the visual information) so as to correspond to the viewer'sperspective of the first virtual display surface. The same may likewiseapply for the display of third visual information 301 on the at leastone second virtual display surface.

FIG. 1A schematically illustrates first visualisation information 101which may correspond to first presence capture information captured by afirst presence capture device at first presence capture location 103“A”. FIG. 1A also schematically illustrates second visualisationinformation 201 which may corresponds to second presence captureinformation captured by a second presence capture device at a secondpresence capture location 203 “B”.

FIG. 1B shows a plan view of a map illustrating first, second and thirdgeographical locations A 103, B 203 and C 303 respectively. The firstand second viewpoint locations may correspond to presence capturelocations at which a plurality of viewpoints 102 a′, 102 b′ and 102 c′have been captured and likewise, at the second geographical location B203, a plurality of images have been captured at differing viewpoints201 a′, 201 b′ and 201 c′. The second geographical location B is locatedin a direction 112 with respect to the first geographic location 103.Furthermore, the geographic locations B and A are separated by aseparation distance 112 a. The third visualisation information 301 maycorrespond to a viewpoint 301 a′ as perceived from a third geographiclocation C 303 which represents a view of an area between the first andsecond geographic locations A 103 and B 203. In some examples, the thirdvisual information may relate to a route or way between the first andthe second locations.

The representations of first and second visualisation information101,201 shown in FIG. 1A are simplified. It is to be appreciated thateach visualisation information may offer 360/720 degree views. Eachvisualisation information 101, 201 may comprise a plurality of differingfields of view 102 a′-c′, 201 a′-′b at a plurality of differing viewingdirections 102 a-c, 201 a-b so as to virtually visually represent thereal world visual environment at the locations A and B.

Examples of the disclosure may create a link between two contentstreams/files of presence capture information that provide the first andsecond visualisation information for displaying first and second views.Such a link is provided with the creation of a virtual object such as a“virtual tube”.

FIG. 2 schematically and conceptually illustrate elements of thevisualisation 400, namely a virtual tube leading to/from viewpoints 102a′-102 c′ of the first and second visualisation information 101, 201. Insense, the virtual tube may be given by a straight line from a firstlocation A to a second location B. The straight line may correspond to avirtual line of sight of location B from location A. The tube/tunnel mayhave some application specific or user definable diameter orcircumference such that the opening at each end covers a given area. Thetwo openings need not be of the same size, nor do they need to be round.In terms of viewing content, the tube/tunnel further has inside walls,an inner surface, the area of which will depend on the length of thetube/tunnel as well as its diameter. The length may correspond to thereal world distance between the two locations or at least be dependentupon the real world separation distance. Furthermore, the length of thetube may depend on the amount and relevance of information and visualcontent available between the two presence capture locations. The scaleat which the second visual information of the second location ispresented need not be relative to the real world separation distance.Instead, in certain examples, the scale of the presented second visualinformation may generally correspond a scale the user would perceive ifthe user were viewing the second visual information at the secondlocation.

In the example of a virtual object 401 shown in FIG. 2, the virtualobject takes the form of a virtual tube/tunnel linking the first andsecond visualisation information 101 and 201. However, the virtualobject 401 may be other shapes, not least for example: a cone, afrusto-conical shape, a cylinder, a polyhedron, a hexahedron, a prism, apyramid, a frustum. In some examples, it may comprise an open endedelongate shape the distal and proximal ends of which need not necessarybe of the same size, such as for a frusto-conical shape (apex truncatedcone) and a frustum (apex truncated pyramid). The distal (apex) andproximal (base) end surfaces of the virtual object 401 need not beparallel but could, in some examples, be non-parallel. In some examples,the shape may change and adapt, e.g., based on the user's viewing angle.

The proximal end 405, e.g. open ended base of the virtual object 401 maybe located on an image plane (which in this case corresponds to theimage/display plane of the displayed part 101 a of the first visualinformation). The virtual object 401 may be considered to extendbeyond/behind the image plane such that its distal end/apex end 406 maybe considered to virtually project inwardly beyond the image plane in adirection away from the viewer, i.e. such that the virtual object has alongitudinal/elongate dimension/virtual depth extent 407.

The virtual display surfaces 403 a′ and 404 a′ may define a virtualboundary within which a part of the second and third visualisationinformation 201, 301 may be rendered/displayed. The virtual displaysurfaces 403 a′, 404 a′ may provide a viewport/window for the parts ofthe second and third visualisation information 201, 301 to berendered/displayed on, i.e. they provide a virtual surface onto whichthe respective visualisation information is mapped/rendered for display.

A size/dimension 406 a of the distal end 406 surface/first virtualdisplay surface 403 a′ may be dependent on a separation distance 112 abetween the first and second geographical locations 103, 203, e.g. thefurther away the second location 203 is from the first location 103, thesmaller “viewport/window” for displaying a part of the secondvisualisation 201. Whereas the closer the second location 203 is to thefirst location 103, the larger the viewing window. Likewise, asize/dimension 405 a of the proximal end surface 405/second virtualdisplay surface 404 a′ may be dependent on the separation distance 112a.

Also a virtual depth 407 (longitudinal/elongate dimension) of thevirtual object 401 may be dependent on the separation distance 112 abetween the first and second geographical locations 103 and 203. Forexample, the further away the second location 203 is from the firstlocation 103, the longer the virtual object 401 (one might consider thisto correspond to a virtual tunnel, on a display end of which isdisplayed the second visual information 201 and on a part of the innersurface of which is displayed the third visual information 301, thatacts to visually link the display of the first and second visualinformation 101 and 201). Advantageously, this may provide an intuitiveindication as to physical distances between presence capture locations.

FIG. 3A presents a conceptual schematic illustration of a virtual tubethat may be established between locations A and B. The tube/tunnel issimplified in this Figure to only show an inner wall visualisation ofcontent that is available for the area located between the two presencecapture locations A and B.

Thus, the view in FIG. 3A may be considered as corresponding to a partof the inner wall of the tube visualised in FIG. 2.

As shown in FIGS. 3A and 3B, the at least part 301 a of the third visualinformation 301 may comprise a view 301 a′ from a third geographicallocation 303. In such a manner, the third visual information 301 maycomprise a view between the first and second geographic locations 101and 201. Moreover, the arrangement and configuration of the display ofthe first, second and third visual information 101, 201, 301 using thevirtual object 401 and virtual display surfaces 403 a′, 404 a′ thereonmay provide a visual link between the displays of the first and secondgeographic locations 103, 203 which may provide a more intuitive andless intrusive display of the first and second visual information 101,201 and may thereby provide a more immersive user experience for theviewer. In the visualisation shown in FIG. 3B, a viewer would only see asingle “slice” or “direction” of the 360/720 degree view that isavailable at location B by viewing it, through the visualisation, fromlocation B.

With reference to FIG. 3A, initially, a user/viewer may be currentlyviewing/perceiving first visual information 101 as if he were located atposition A, i.e. a virtual location of the viewer may be considered tobe the location 103. The viewer's view/field of view may correspond tosome 180 degrees of the overall view in the horizontal direction. Forthe sake of simplicity, FIG. 3A only shows the 180 degree view, but itis to be appreciated that the full 360 degree view may be able to bepresented (e.g. if a user were to turn his/her head around). The viewdisplayed to the viewer corresponds to a view of the visual information101 in a direction 114 that is dependent on the viewer's real worldpoint of view 113, i.e. the user's real point of view determines thepoint of view displayed.

FIG. 3B provides a further illustration, where the viewer turns his/herhead. The view displayed to the viewer corresponds to a view of thevisual information in a direction 114 a corresponding to the viewer'sreal world point of view 113a.

By looking at a certain direction, 113 a which is towards the direction112 of location B, a visualisation 400 may be generated and displayed(the visualisation 400 is shown in greater detail in FIGS. 4A and 4B).This visualisation 400 takes the form of a virtual tube/tunnel which mayappear and whose opening may become visible to the viewer as his hergaze lingers in the direction 112. This virtual tube offers the viewer avisualisation 400 of visual content 201 a from a second location B whichis displayed at one end of the virtual tube, as well as a visualisation400 of visual content 301 a between the two locations (e.g. an image ofthe view between the two locations) which is displayed on an innersurface of the virtual tube. The viewer may peek at the visualisation301 a by tilting his/her head and thus changing his/her perspectiveviewpoint. The viewer may be allowed to alter the viewpoint that thevirtual tube offers of the second location B via controls or gestures(e.g. alter the direction so the view of the second visual information201, or the relative sizes of the visualisation 400). Alternatively, theviewpoint direction of the second visual information 201 mayautomatically move around such that the viewer may get an overview ofthe content of the second location B, whist still virtually remaining atlocation A. There may also be hints of at least a third location towhich the viewer may access by navigating to/entering the virtual secondlocation B.

Certain examples of the present disclosure may enable a viewer toswitch/transition between providing a virtual reality display of thefirst visual information 101 to providing a virtual reality display ofthe second visual information 201. This may involve switching fromaccessing/receiving a first stream of visual presence captureinformation associated with a first presence capture location toaccessing/receiving a stream of second visual presence captureinformation associated with a second presence capture location.

Such switching/transitioning between the virtual reality display offirst and second visual information 101, 201 may be in response toreceiving a user input for the same, not least for example a gesture,voice input, touch input or user actuation of a user input device, suchas to select the displayed second visualisation information 201. In someexamples, the viewer may “climb into” or enter the virtual tube/tunnelto navigate through it, i.e. the displayed visualisation information(s)are modified so as to create the appearance of the viewer moving from afirst virtual location, through the tunnel, to a second virtuallocation. Such examples may thereby provide an intuitive and seamlessswitching between the first and second locations A and B.

In a first mode of operation, a viewer may be able to interact/visuallynavigate around/pan around the display of the first visual information101 whereas, after such a switch/transition, a second mode of operationmay come into being in which enables a viewer to interact/visuallynavigate around/pan around the second visual information 201, i.e. suchthat a viewer's head/gaze movement may be tracked and used to alter theperceived point of view at the second presence capture location.

Without limiting the scope of the claims, certain examples of thepresent disclosure may provide an improved method and apparatus forexperiencing presence capture content and may enable seamless switchingbetween presence capture locations (i.e. seamless switching betweenmodes and the viewing of presence capture content, captured by differingpresence capture devices at differing presence capture locations).

In various examples of the disclosure, the display of the first visualinformation 101 may correspond to the provision of a virtual realitydisplay of the first visual information 101, i.e. a virtual realityimmersive display of the environment of the first geographic location103 in which a viewer is able to view around and pan across the displayof the first visual information 101, for example such that the viewer'svirtual point of view in the virtual reality display is dependent upon adetermination of a viewer's real world point of view 113 when using avirtual reality display.

The viewpoint 102 a′ and its direction 102 a of the first visualinformation 101 to be displayed may be selected and determined based ona viewer's real world point of view 113. Likewise, the viewpoint of thesecond visual information 201 may likewise be dependent on thedetermined real world point of view 113 of a viewer.

The position of the virtual object 401 and thus the position of virtualdisplay surfaces 403 a′, 404 a′ and thus the position of the second andthird visual information 201, 301 may be dependent upon one or more ofthe determined direction between the first and second geographiclocations 103, 203 and a real world point of view 113 of a viewer.

FIG. 4A shows an example of a visualisation 400 as it would be perceivedby a viewer in accordance with an example of the present disclosure. Atleast part 101 a of first visual information 101 is displayed.Overlaying this, the visualisation 400 is generated and displayed in theform of a three-dimensional virtual tunnel 401 having an open-endedproximal end 405 and a distal end 406 (as per FIG. 2). A distal end 406surface may define a virtual display surface 403 a on which a display ofat least a part 201 a of the second visual information 201 may bedisplayed (not shown). At least a part of an inner surface 404 of thevirtual tunnel 401 defines a second virtual display surface 404 a ontowhich at least a part 301 a of third visual information 301 is displayedin an overlaying manner. The overlay of the differing visual informationmay be opaque, semi-opaque, semi-transparent and/or the like. In theexample shown in FIG. 4A, the viewer's real world point of viewdirection 113 a is co-aligned with the direction 112 of the secondgeographical location 203 with respect to the first geographicallocation 103. With such a configuration, the cross-sectional shape ofthe virtual tunnel 401 is perceived to be circular. However, in theexample of FIG. 4B, the real world point of view of the viewer 113 isnot co-aligned with the direction 112 nor aligned with the primary axis402 of the virtual tunnel 401. In this scenario, from such a viewpointperspective, the cross-sectional shape of the virtual tunnel 401 wouldbe perceived to be ellipsoidal. Accordingly, the shape 402 a of thedistal end 406 surface/first virtual display surface 403 a and its innerwall surface/second virtual display surface 404 a may be duly modifiedin view of the perspective of the viewer, i.e. in dependence on theviewer's real world point of view 113 (as may be determined by head orgaze tracking system) such that the virtual perspective of the virtualobject 401 is dependent on the viewer's real world point of view 113.This may allow for the user to better view the third visual information,e.g. in a given direction.

The viewer's real world point of view 113 may be determined by, forexample, accelerometers, electronic gyroscopes or electronic compasses.Alternatively, or in a addition, pupil tracking technology, based forexample on computer vision, may be used to track movement of a user'seye or eyes and to direction of a user's gaze and hence viewer's realworld point of view 113.

In some examples (not shown) the virtual object 401 may comprise atleast one virtual exterior surface. Such a virtual exterior surface mayitself provide a virtual display surface for visual information, or may,instead, simply be “transparent”, i.e. so as to enable display of visualinformation there-through. However, in certain examples, the virtualexterior surface may be non-transparent/opaque/used as a virtual displaysurface on which further visual information is displayed. In such cases,the virtual exterior surface may occult one or more of the first virtualdisplay surface 403 a and the at least second virtual display surface404 a. In some examples, the virtual exterior surface may be consideredto be in the foreground of the image, thereby occulting the background,virtual, inner surface.

FIGS. 4A and 4B schematically illustrate how a viewer may “peek” into avirtual tube by tilting his/her head/view to alter his/her perspectiveand the virtual perspective of the virtual tube, i.e. so as to revealmore of the inner surface/second virtual display surface 404 a to beable to see more of the third visualisation information 301.

The display of the visualisations may be in response to one or more of:

-   -   Determining 802 that a direction of a viewer's real world point        of view 113 is aligned with the direction 112 of the second        geographic location 203 with reference to the first geographic        location 103 (or at least that the direction is within a field        of view of the viewer's real world point of view 113);    -   detecting a user input (not least for example gestures, voice        input, touch input or user actuation) of a user input device;    -   geographical proximity of the first geographic location 103 with        respect to the second geographic location 203;    -   temporal proximity of a time of capture of the first visual        information 101 with respect to a time of capture of the second        visual information 201; context information; and    -   a user profile.

FIGS. 5A and 5B schematically illustrate additional visualisationinformation 501, 502, 503 that may be provided in addition to the thirdvisualisation information 301 a (which corresponds to a view between thefirst and second locations A and B). Such additional visualisations maycomprise, not least for example graphics 501, text 502 and combinationof graphics and text 503 that may provide additional visualisations andinformation to a viewer, not least for example current weather andadvertising information as well as other textual information related tothe area between the locations A and B.

In some examples, a viewer may select content that is visualised in thevirtual tube for closer inspection. The viewer may also use visualisedcontent as a shortcut to at least a third presence capture location ifavailable. This may create a new virtual tube opening or it may createan intersection/connection within the first virtual tube (such aconnection may be temporary).

The generation, availability and display of virtual tubes betweenpresence capture locations may be based on parameters such asgeographical proximity of the presence capture locations, closeness intime of capture of the presence capture information, other contextdependent parameters or a combination of the same.

The transitioning between a first mode in which a viewer perceives avirtual reality environment of the first present capture location to theviewer perceiving a virtual reality environment of the second presencecapture location may comprise the viewer navigating through the virtualobject 401, which may occur, not least for example in response to a userinput.

Alternatively, such navigation may be automated and form part of a“virtual tour”. For example, in some embodiment, an automated navigationsuch as a “virtual tour” may indicate to the user the direction of thenext presence capture location by means of automatically presenting thelocation of the corresponding virtual tube opening.

FIG. 6 schematically illustrates a network of a plurality of presencecapture locations 103, 203 and 603 along with a plurality of virtualtunnels 401, 601 that enable a viewer, when viewing visual presencecapture information 101, 201, 601 from one of the presence capturelocations 103, 203, 603, to visually link/connect one of the presencecapture locations 103 with another of the presence capture locations203. As is shown in FIG. 6, a particular presence capture location 103,e.g. represented by first visual information 101, may have a pluralityof virtual tunnels 401, 601, 601 a and corresponding visualisationsassociated with the same 400, 600, 600 a.

As shown in FIG. 6, in addition to a first visualisation 400, one ormore further visualisations 600 may be displayed that visuallyinterconnect the first visual information 101 that is displayed to adisplay of at least a part of fourth visual information 602.

FIG. 6 presents an illustration of possible virtual tube connectionsbetween presence capture locations based on what a viewer is currentlylooking at and a selected path 604 that is currently offered to theviewer.

In some examples, a viewer may follow a selected path/network ofpresence capture locations and may find a virtual tube at a presencecapture location corresponding to another path/network of presencecapture locations. The viewer may be presented with instructions on howto return to said first path/network while enjoying the content of thesecond location. For example, a virtual tube may be one that features anintersection where the main direction is towards the next presencecapture location and a secondary direction is towards a presence capturelocation related to the first path/network. Thus, a service may adaptthe locations and tubes the viewer is offered such that at least twopaths/networks are at least partially combined into a single experience.

In some examples, a viewer may be offered a virtual tour of a city, i.e.via navigating through the network of FIG. 6, where each node representspresence capture locations of a city interlinked via a network of usernavigable virtual tubes. Such a tour may be created for each userindividually based on parameters that may include user preferencesettings. On the other hand, some presence capture locations may berestricted, e.g. for commercial reasons, and they may be available asfixed pay-per-view features or made available only for limited sets ofusers.

In some examples, a further visualisation 600 a may be displayed whichvisually links a displayed at least part of the first visual information101 to a display of at least part of a fourth visual information 602(the fourth visual information 602 relating to a further presencecapture location). In yet other examples (not shown), a furthervisualisation may visually link a displayed at least part 301 a of thethird visual information 301 to a display of at least a part of fifthvisual information (the fifth visual information corresponding to afurther presence capture location). In yet further examples, the furthervisualisation may visually link one visualisation to a yet furthervisualisation.

FIG. 7 illustrates a larger network 700 of presence capture locations701 with interconnecting virtual tubes/tunnels/passageways 702. Thesystem may adaptively control available paths/routes offered to aviewer. The nodes 701 represent available presence capture locations(i.e. locations for which presence capture information is available)that are interconnected with one another via links 702 (i.e.visualisation of user navigable virtual tunnels linking the nodestogether).

In the network map 700 of FIG. 7, a plurality of presence capturelocations 700 are shown as nodes in the map that are interconnected viavirtual objects/virtual tunnels 702. Not only do the virtualobjects/virtual tunnels 702 interconnect the nodes/presence capturelocations 701, but also the virtual objects/virtual tunnels 702 mayinterconnect with one another. For example the virtual object/tunnel 703may interconnect with a further virtual object/virtual tunnel 704. Sucha network of virtual tunnels 702 linking presence capture locations 702may provide a user navigable pathway through which a viewer may navigatefrom one virtual presence location to another through the virtual tunnel701. Such viewer navigation may be upon user control/input or may beautomated as part of a tour of the virtual network, i.e. so as toprovide a predefined route through the virtual network that may enable avirtual sightseeing tour of a region.

FIG. 8 schematically illustrates a method 800 according to an example ofthe present disclosure.

In block 801, at least a part 101 a of first visual information 101 thatis a view 102 a′, from a first geographical location 103 is displayed.

In block 802, a visualisation 400 is generated that is configured tovisually link the display of the at least a part 101 a of the firstvisualisation information 101 with a display of at least a part 201 a ofsecond visual information 201 that is a view 202 a′ from a secondgeographical location 203. Such a generation of the visualisation maycomprise, in sub-block 802 a, determining (i.e. either via calculatingor receiving) a direction 112 of the second geographical location 203with respect to the first geographical location 103. Such a direction112 may correspond to a virtual line of sight of the second geographicallocation 203 with respect to the first geographical location 103. Insub-block 802 b, a virtual object 401 is defined having: a virtualprimary axis 402 whose alignment/orientation is dependent on thedetermined direction 112; a virtual distal end surface 403, at least apart of which defines a virtual display surface 403 a; and at least onevirtual inner surface 404, at least part of which defines at least asecond virtual display surface 404 a.

In sub-block 802 c, at least a part 201 a of the second visualinformation 201 is displayed (e.g. simultaneously with and/or overlayingthe displayed first visual information 101) on the first virtual displaysurface 403 a. The position of the first virtual display surface 403 aand thus the position of the display of the second visual information201 may depend on the determined direction 112 as well as a determinedreal world point of view of a viewer 113.

In sub-block 802 d, at least a part 301 a of third visual information301 is displayed on the second virtual display surface 404 a.

The block diagram of FIG. 8 represents one possible scenario amongothers. The order of the block shown is not absolutely required so inprinciple, the sequence of blocks can be performed out of order. Incertain examples, one or more of the blocks may be performed in adifferent order or overlapping in time, in series or in parallel.

The blocks illustrated in FIG. 8 may represent actions in a methodand/or sections of instructions/code in the computer program 904.

As will be appreciated, any such computer program instructions may beloaded onto a computer or other programmable apparatus (i.e., hardware)to produce a machine, such that the instructions when performed on theprogrammable apparatus create means for implementing the functionsspecified in the blocks. These computer program instructions may also bestored in a computer-readable medium that can direct a programmableapparatus to function in a particular manner, such that the instructionsstored in the computer-readable memory produce an article of manufactureincluding instruction means which implement the function specified inthe blocks. The computer program instructions may also be loaded onto aprogrammable apparatus to cause a series of operational actions to beperformed on the programmable apparatus to produce acomputer-implemented process such that the instructions which areperformed on the programmable apparatus provide actions for implementingthe functions specified in the blocks.

Examples of the present disclosure may take the form of a method, anapparatus or a computer program 904. Accordingly, examples may beimplemented in hardware, software or a combination of hardware andsoftware.

FIG. 9 schematically illustrates a block diagram of an apparatus 900.The apparatus 900 comprising a controller 901. The controller 901 isconfigured to receive user input commands (i.e. from the user inputdevice 908) and is configured to provide output commands (i.e. tocontrol a display 909).

Implementation of the controller 901 can be in hardware alone (forexample processing circuitry comprising one or more processors andmemory circuitry comprising one or more memory elements), have certainaspects in software including firmware alone or can be a combination ofhardware and software (including firmware).

The controller 901 may be implemented using instructions that enablehardware functionality, for example, by using executable computerprogram instructions in a general-purpose or special-purpose processorthat may be stored on a computer readable storage medium (disk, memoryetc.) or carried by a signal carrier to be performed by such aprocessor.

In the illustrated example, the apparatus 900 comprises a controller 901which is provided by a processor 902 and memory 903. Although a singleprocessor and a single memory are illustrated in other implementationsthere may be multiple processors and/or there may be multiple memoriessome or all of which may be integrated/removable and/or may providepermanent/semi-permanent/dynamic/cached storage.

The memory 903 stores a computer program 904 comprising computer programinstructions 905 that control the operation of the apparatus 900 whenloaded into the processor 902. The computer program instructions 905provide the logic and routines that enable the apparatus 900 to performthe functionality and method described above.

The at least one memory 903 and the computer program instructions 905are configured to, with the at least one processor 902, cause theapparatus 900 at least to perform the functionality and method describedabove and not least the method described, for example with respect toFIG. 8.

The processor 902 is configured to read from and write to the memory903. The processor 902 may also comprise an input interface 906 viawhich data (such as visualisation information from storage 908, whichmay be local or remote of the device 910) and/or commands are input tothe processor 902, and an output interface 907 via which data and/orcommands (i.e. to control a display 909 to display the various parts ofthe visualisation information and visualisations) are output by theprocessor 902.

The computer program 904 may arrive at the apparatus 900 via anysuitable delivery mechanism 911. The delivery mechanism 911 may be, forexample, a non-transitory computer-readable storage medium, a computerprogram product, a memory device, a record medium such as a compact discread-only memory, or digital versatile disc, or an article ofmanufacture that tangibly embodies the computer program 904. Thedelivery mechanism 911 may be a signal configured to reliably transferthe computer program 904.

The apparatus 900 may receive, propagate or transmit the computerprogram 904 as a computer data signal.

The apparatus 900 may be comprised in a device 910, for example: aclient device, a server device, a mobile cellular telephone, a wirelesscommunications device, a hand-portable electronic device, a displaydevice or a virtual reality display system etc. or a module or chipsetfor use in any of the foregoing.

Examples of the present disclosure and the functionality provided bysuch examples have been described above and also with reference to theFigures and schematic block diagrams described. It will be understoodthat such functionality and each block (of the flowchart illustrationsand block diagrams), and combinations of blocks, can be implemented bycomputer program instructions 905 of a computer program 904. Theseprogram instructions 905 may be provided to one or more processor(s)902, processing circuitry or controller(s) such that the instructions,when executed, create means for causing implementing the functionsspecified in the block or blocks. The computer program instructions 905may be executed by the processor(s) 902 to cause a series of operationalsteps/actions to be performed by the processor(s) 902 to produce acomputer implemented process such that the instructions which execute onthe processor(s) 902 provide steps for implementing the functionsspecified in the block or blocks.

Accordingly, the present disclosure supports: combinations of means forperforming the specified functions; combinations of actions forperforming the specified functions; and computer programinstructions/algorithm 905 for performing the specified functions. Itwill also be understood that each function, and combinations offunctions, can be implemented by special purpose hardware-based systemswhich perform the specified functions or actions, or combinations ofspecial purpose hardware and computer program instructions 905.

Although examples of the apparatus 900 have been described above interms of comprising various components, it should be understood that thecomponents may be embodied as or otherwise controlled by a correspondingcontroller or circuitry such as one or more processing elements orprocessors of the apparatus. In this regard, each of the componentsdescribed above may be one or more of any device, means or circuitryembodied in hardware, software or a combination of hardware and softwarethat is configured to perform the corresponding functions of therespective components as described above.

References to ‘computer-readable storage medium’, ‘computer programproduct’, ‘tangibly embodied computer program’ etc. or a ‘controller’,‘computer’, ‘processor’ etc. should be understood to encompass not onlycomputers having different architectures such as single/multi-processorarchitectures and sequential (Von Neumann)/parallel architectures butalso specialized circuits such as field-programmable gate arrays (FPGA),application specific circuits (ASIC), signal processing devices andother devices. References to computer program, instructions, code etc.should be understood to encompass software for a programmable processoror firmware such as, for example, the programmable content of a hardwaredevice whether instructions for a processor, or configuration settingsfor a fixed-function device, gate array or programmable logic deviceetc.

As used in this application, the term ‘circuitry’ refers to all of thefollowing:

-   -   (a) hardware-only circuit implementations (such as        implementations in only analogue and/or digital circuitry) and    -   (b) to combinations of circuits and software (and/or firmware),        such as (as applicable): (i) to a combination of processor(s)        or (ii) to portions of processor(s)/software (including digital        signal processor(s)), software, and memory(ies) that work        together to cause an apparatus, such as a mobile phone or        server, to perform various functions) and    -   (c) to circuits, such as a microprocessor(s) or a portion of a        microprocessor(s), that require software or firmware for        operation, even if the software or firmware is not physically        present.

This definition of ‘circuitry’ applies to all uses of this term in thisapplication, including in any claims. As a further example, as used inthis application, the term “circuitry” would also cover animplementation of merely a processor (or multiple processors) or portionof a processor and its (or their) accompanying software and/or firmware.The term “circuitry” would also cover, for example and if applicable tothe particular claim element, a baseband integrated circuit orapplications processor integrated circuit for a mobile phone or asimilar integrated circuit in a server, a cellular network device, orother network device.

In one example, the apparatus 900 is embodied on a hand held portableelectronic device, such as a mobile telephone, wearable computing deviceor personal digital assistant, that may additionally provide one or moreaudio/text/video communication functions (e.g. tele-communication,video-communication, and/or text transmission (Short Message Service(SMS)/Multimedia Message Service (MMS)/emailing) functions),interactive/non-interactive viewing functions (e.g. web-browsing,navigation, TV/program viewing functions), music recording/playingfunctions (e.g. Moving Picture Experts Group-1 Audio Layer 3 (MP3) orother format and/or (frequency modulation/amplitude modulation) radiobroadcast recording/playing), downloading/sending of data functions,image capture function (e.g. using a (e.g. in-built) digital camera),and gaming functions.

The apparatus 900 may be provided in a module. As used here ‘module’refers to a unit or apparatus that excludes certain parts/componentsthat would be added by an end manufacturer or a user.

FIG. 10 schematically illustrates a connection creation system forbuilding connections between presence capture locations, e.g. creatingvirtual tunnels/visualisations between nodes/presence capture locations.In this method, presence capture information of a presence capturelocation may be analysed. User settings, context analysis and servicesettings may also be involved in analysis of the presence captureinformation. As a result of the analysis, a connection to a current pathmay be created. Alternatively, a connection to a secondary path may bemade or a new path may be created.

Examples of the present disclosure provide a method, computer program,user interface and apparatus comprising various modules, means orcircuitry that provide the functionality described above and forperforming the actions of the method. The modules, means or circuitrymay be implemented as hardware, or may be implemented as software orfirmware to be performed by a computer processor 902. In the case offirmware or software, examples of the present disclosure can be providedas a computer program 904 product including a computer readable storagestructure embodying computer program instructions 905 (i.e. the softwareor firmware) thereon for performing by the computer processor 902.

The apparatus 900 may be provided in an electronic device, for example,mobile terminal, according to an exemplary embodiment of the presentdisclosure. It should be understood, however, that a mobile terminal ismerely illustrative of an electronic device that would benefit fromexamples of implementations of the present disclosure and, therefore,should not be taken to limit the scope of the present disclosure to thesame. While in certain implementation examples the apparatus 900 may beprovided in a mobile terminal, other types of electronic devices, suchas, but not limited to: virtual reality display devices, hand portableelectronic devices, wearable computing devices, portable digitalassistants (PDAs), mobile computers, desktop computers, televisions,gaming devices, laptop computers, cameras, video recorders, GPS devicesand other types of electronic systems, may readily employ examples ofthe present disclosure. Furthermore, devices may readily employ examplesof the present disclosure regardless of their intent to providemobility.

The examples of the present disclosure and the accompanying claims maybe suitably combined in any manner apparent to one of ordinary skill inthe art.

Features described in the preceding description may be used incombinations other than the combinations explicitly described. Althoughfunctions have been described with reference to certain features, thosefunctions may be performable by other features whether described or not.Although features have been described with reference to certainexamples, those features may also be present in other examples whetherdescribed or not. Although various examples of the present disclosurehave been described in the preceding paragraphs, it should beappreciated that modifications to the examples given can be made withoutdeparting from the scope of the invention as set out in the claims.

Without limiting the scope of the claims, certain particular examples ofthe present disclosure may prove an improved display both first presencecapture information (of a first presence capture location) as well as atleast a portion of second presence capture information (of a secondpresence capture location) simultaneously. This may be the case where aviewer, being virtually present at a first presence capture location,may wish additionally to see a view from another presence capturelocation, e.g. to decide whether or not to transition/switch to beingvirtually at the second presence capture location. For example, firstpresence capture information could be primarily displayed (i.e. suchthat a viewer may perceive/experience the environment of the firstpresence capture location and can be considered to be “virtually” at thefirst presence capture location) but also a part of second presencecapture information may also be displayed. This may be done so as toenable a viewer to be virtually at the first presence location but alsoto see a view from a second presence capture location (whilst remainingvirtually in the first virtual presence capture location). This mayenable the viewer to decide whether or not to switch or navigate fromthe first presence capture location to the second presence capturelocation so as to primarily view the second presence capture informationand perceive/experience the environment of the second presence capturelocation (such that the viewer might be considered to be “virtually” atthe second presence capture location).

Without limiting the scope of the claims, certain examples of thepresent disclosure seek to provide an improved method and apparatus fordisplaying presence capture information. The user experience ofviewing/perceiving presence capture information of a presence capturelocation via a presence capture information rendering device may befully immersive and may feel very real to the viewer. Certain examplesof the present disclosure seek to enable the display of first and secondpresence capture information in an intuitive way that is lessdisorientating, intrusive and perturbing to a viewer thereby reducingany adverse effect on a viewer's level of immersion and user experiencewhen consuming presence capture content. Certain examples of the presentdisclosure seek to generate and display a visualisation 400 thatvisually links a display of first presence capture information to adisplay of second presence capture information so as to provide a moreintuitive link between the two displays of presence capture informationand to facilitate switching between presence capture locations. Certainexamples may seek to provide a simultaneous display of first and secondpresence capture information in an intuitive manner that is lessdisorientating or distracting to a viewer who may be deeply immersed inviewing the presence capture information, e.g. in a virtual realityenvironment. This may enhance a viewer's level of immersion and improvethe viewer's user experience of consuming presence capture content.Certain examples may enable a viewer to better perceive a relativelocation/displacement of the first and second presence capturelocations, thereby providing a more intuitive and immersive display ofpresence capture information.

The term ‘comprise’ is used in this document with an inclusive not anexclusive meaning. That is any reference to X comprising Y indicatesthat X may comprise only one Y or may comprise more than one Y. If it isintended to use ‘comprise’ with an exclusive meaning then it will bemade clear in the context by referring to “comprising only one . . . ”or by using “consisting”.

In this description, references to “a/an/the” [feature, element,component, means . . . ] are to be interpreted as “at least one”[feature, element, component, means . . . ] unless explicitly statedotherwise. In this description, the wording ‘connect’, ‘couple’ and‘communication’ and their derivatives mean operationallyconnected/coupled/in communication. It should be appreciated that anynumber or combination of intervening components can exist (including nointervening components).

In this description, reference has been made to various examples. Thedescription of features or functions in relation to an example indicatesthat those features or functions are present in that example. The use ofthe term ‘example’ or ‘for example’ or ‘may’ in the text denotes,whether explicitly stated or not, that such features or functions arepresent in at least the described example, whether described as anexample or not, and that they can be, but are not necessarily, presentin some or all other examples. Thus ‘example’, ‘for example’ or ‘may’refers to a particular instance in a class of examples. A property ofthe instance can be a property of only that instance or a property ofthe class or a property of a sub-class of the class that includes somebut not all of the instances in the class.

In the above description, the apparatus described may alternatively orin addition comprise an apparatus which in some other embodimentscomprises a distributed system of apparatus, for example, aclient/server apparatus system. In examples of embodiments where anapparatus provided forms (or a method is implemented as) a distributedsystem, each apparatus forming a component and/or part of the systemprovides (or implements) one or more features which collectivelyimplement an example of the present disclosure. In some examples ofembodiments, an apparatus is re-configured by an entity other than itsinitial manufacturer to implement an example of the present disclosureby being provided with additional software, for example by a userdownloading such software, which when executed causes the apparatus toimplement an example of the present disclosure (such implementationbeing either entirely by the apparatus or as part of a system ofapparatus as mentioned hereinabove).

The above description describes some examples of the present disclosurehowever those of ordinary skill in the art will be aware of possiblealternative structures and method features which offer equivalentfunctionality to the specific examples of such structures and featuresdescribed herein above and which for the sake of brevity and clarityhave been omitted from the above description. Nonetheless, the abovedescription should be read as implicitly including reference to suchalternative structures and method features which provide equivalentfunctionality unless such alternative structures or method features areexplicitly excluded in the above description of the examples of thepresent disclosure.

Whilst endeavouring in the foregoing specification to draw attention tothose features of examples of the present disclosure believed to be ofparticular importance it should be understood that the applicant claimsprotection in respect of any patentable feature or combination offeatures hereinbefore referred to and/or shown in the drawings whetheror not particular emphasis has been placed thereon.

Various examples of the present disclosure may provide a user interfaceand system for seamless switching between presence capture locationsusing a visualisation, referred to as “virtual tubes”. The virtual tubemay correspond to a tube, cone or tunnel that is created between atleast two virtual locations to visualise a smooth transition between therepresentations of the locations.

A viewer who views a first location may assess the relation the secondlocation to the first location by viewing the tube opening. The viewthrough the tube opening may offer a view to at least the secondlocation whilst the inside walls of the tube may give a visualisation ofwhat appears between the two locations. With such a visualisation, theviewer may ascertain as to whether or not the second location is ofinterest to the viewer and if the viewer would desire to view the secondlocation in further detail. The position of the opening may correspondto the physical position of at least a second location in relation tothe first location. The virtual tube opening may become visible, e.g.through a gesture, by looking in the direction of the virtual opening,etc. in a way such that it is not intrusive or distracting to the viewerwhen immersed in the representation of the first location. The viewermay also enter into the tube in order to access the second location andview its content. During such a transition traversing through the tube,content between the two locations may be presented to the viewer, forexample, a representation of a view between the two locations.

1-15. (canceled)
 16. An apparatus comprising: at least one processor;and at least one memory including computer program code, the at leastone memory and the computer program code configured to, with the atleast one processor, cause the apparatus to perform at least thefollowing: display at least a part of first visual information that is afirst view, from a first geographical location; generate a visualisationconfigured to visually link the display of the at least a part of thefirst visual information with a display of at least a part of secondvisual information that is a second view from a second geographicallocation, wherein generating the visualisation comprises: determining adirection of the second geographical location with respect to the firstgeographical location; defining a virtual object having: a virtualprimary axis aligned in dependence on the direction, a virtual distalend surface, at least a part of which defines a first virtual displaysurface, and at least one virtual inner surface, at least a part ofwhich defines at least a second virtual display surface; displaying onthe first virtual display surface at least a part of the second visualinformation; displaying on the at least second virtual display surface,at least a part of third visual information; and enable a viewer tovisually navigate through the virtual object.
 17. The apparatus of claim16, wherein a shape of the virtual object comprises at least one of moreof: a tube, a tunnel, a cylinder, a cone, a frusto-conical shape, apolyhedron, a hexahedron, a prism, a pyramid, a frustum, an open endedthree dimensional shape and an elongate shape.
 18. The apparatus ofclaim 16, wherein a size of the first virtual display surface and/or avirtual depth of the virtual object is dependent on a separationdistance between the first and second geographical locations.
 19. Theapparatus of claim 16, wherein a virtual depth of the virtual object isdependent on a separation distance between the first and secondgeographical locations.
 20. The apparatus of claim 16, wherein the atleast a part of the third visual information comprises a view from athird geographical location.
 21. The apparatus of claim 16, wherein oneor more of the first, second and third visual information corresponds toone or more first, second and third images captured at the first, secondand third geographical locations respectively.
 22. The apparatus ofclaim 16 further cause the apparatus to perform at least the following:enable a viewer to visually navigate around the first visualinformation.
 23. The apparatus of claim 16 further cause the apparatusto perform at least the following: switch between a first mode in whicha viewer is able to visually navigate around the first visualinformation to a second mode in which a viewer is able to visuallynavigate around the second visual information.
 24. The apparatus ofclaim 16 further cause the apparatus to perform at least the following:display a further visualisation, wherein the further visualisationvisually links: the displayed at least a part of the first visualinformation to a display of at least a part of fourth visualinformation, the displayed at least a part of the third visualinformation to a display of at least a part of fifth visual information,or the displayed visualisation to a display of a yet furthervisualisation.
 25. The apparatus of claim 16 further cause the apparatusto perform at least the following: provide a network of nodes andinterconnecting links, wherein each node represents a geographicallocation for which visualisation information is available and eachinterconnecting link is a user navigable visualisation linking tworespective geographical locations.
 26. The apparatus of claim 16,wherein the display of the visualisation is in response to one or moreof: determining that a direction of a viewer's real world point of viewis substantially aligned with the direction, detecting a user input, anddetermining a geographical proximity of the first geographic locationwith respect to the second geographic location.
 27. The apparatus ofclaim 16, wherein the display of the visualisation is in response to oneor more of: determining a temporal proximity of a time of capture of thefirst visual information with respect to a time of capture of the secondvisual information, context information, and a user profile.
 28. Amethod comprising: displaying at least a part of first visualinformation that is a first view, from a first geographical location;generating a visualisation configured to visually link the display ofthe at least a part of the first visual information with a display of atleast a part of second visual information that is a second view from asecond geographical location, wherein generating the visualisationcomprises: determining a direction of the second geographical locationwith respect to the first geographical location; defining a virtualobject having: a virtual primary axis aligned in dependence on thedirection, a virtual distal end surface, at least a part of whichdefines a first virtual display surface, and at least one virtual innersurface, at least a part of which defines at least a second virtualdisplay surface; displaying on the first virtual display surface atleast a part of the second visual information; displaying on the atleast second virtual display surface, at least a part of third visualinformation; and enabling a viewer to visually navigate through thevirtual object.
 29. The method of claim 28, wherein a shape of thevirtual object comprises at least one of more of: a tube, a tunnel, acylinder, a cone, a frusto-conical shape, a polyhedron, a hexahedron, aprism, a pyramid, a frustum, an open ended three dimensional shape andan elongate shape.
 30. The method of claim 28, wherein a size of thefirst virtual display surface and/or a virtual depth of the virtualobject is dependent on a separation distance between the first andsecond geographical locations.
 31. The method of claim 28, wherein theat least a part of the third visual information comprises a view from athird geographical location.
 32. The method of claim 28, furthercomprising displaying a further visualisation, wherein the furthervisualisation visually links: the displayed at least a part of the firstvisual information to a display of at least a part of fourth visualinformation, the displayed at least a part of the third visualinformation to a display of at least a part of fifth visual information,or the displayed visualisation to a display of a yet furthervisualisation.
 33. The method of claim 28, wherein the display of thevisualisation is in response to one or more of: determining that adirection of a viewer's real world point of view is substantiallyaligned with the direction, detecting a user input, and determining ageographical proximity of the first geographic location with respect tothe second geographic location.
 34. The method of claim 28, wherein thedisplay of the visualisation is in response to one or more of:determining a temporal proximity of a time of capture of the firstvisual information with respect to a time of capture of the secondvisual information, context information, and a user profile.
 35. Atleast one non-transitory computer readable medium comprisinginstructions that, when executed, perform at least the following:display at least a part of first visual information that is a firstview, from a first geographical location; generate a visualisationconfigured to visually link the display of the at least a part of thefirst visual information with a display of at least a part of secondvisual information that is a second view from a second geographicallocation, wherein generating the visualisation comprises: determining adirection of the second geographical location with respect to the firstgeographical location; defining a virtual object having: a virtualprimary axis aligned in dependence on the direction, a virtual distalend surface, at least a part of which defines a first virtual displaysurface, and at least one virtual inner surface, at least a part ofwhich defines at least a second virtual display surface; displaying onthe first virtual display surface at least a part of the second visualinformation; displaying on the at least second virtual display surface,at least a part of third visual information; and enable a viewer tovisually navigate through the virtual object.